JPWO2003008838A1 - Switchable liquid filled type vibration damping device - Google Patents

Abstract

This invention provides a switching type liquid-in vibration isolating device capable of opening/closing an orifice by changing over between the atmospheric and negative pressure in a switching chamber corresponding to shake and idle vibration, respectively. In order to prevent a pipe, for introducing the atmospheric and negative pressure in the switching chamber, from disconnecting, a first and a second fitting 1, 2 are connected by a vibration isolating substrate 3, a partition member 4, a first and a second diaphragm 5, 6 are disposed within a hollow space thereof, a main liquid chamber 7 and a sub-liquid chamber 8 are interconnected by two inside and outside orifices 12, 13, a equilibrium chamber 9 is formed between the first and second diaphragm 5, 6, a switching chamber 10 is formed between the second diaphragm 6 and the second fitting 2, the center portion of the bottom wall 22 of the second fitting 2 is depressed toward the switching chamber 10, a pipe 11 is pierced into the top 25a of the depressed portion 25 and received in the depressed portion 25, and a plurality of convex portions 29 for interference prevention are outwardly projectively provided on the bottom wall 22 around the depressed portion 25. <IMAGE>

Description

〔Technical field〕
The present invention relates to a switchable liquid-filled type vibration damping device used to support a power unit and other vibrating bodies of an automobile or the like in a vibration-damping manner.
(Background technology)
2. Description of the Related Art Conventionally, a liquid filling type vibration damping device has been used as a mount for supporting a vibrating body such as an automobile engine so as not to transmit vibration to a vehicle body.
As one of the liquid filling type vibration damping devices, a switching type liquid filling vibration damping device that switches the vibration damping characteristics according to two kinds of vibrations having different frequency ranges such as shake vibration and idle vibration has been proposed. ing.
For example, Japanese Patent Application Laid-Open No. 8-270718 discloses a switchable liquid-filled vibration isolator as shown in FIG.
This conventional vibration isolator comprises a first mounting member (101) and a second mounting member having a bottomed cylindrical shape and a bottom wall located at a predetermined distance in the axial direction from the first mounting member (101). A tool (102) and an anti-vibration base (103) made of a rubber elastic body interposed between the first mounting tool (101) and the second mounting tool (102) and connecting them together. A partition member (104), a first diaphragm (105), and a second diaphragm (106) are serially arranged in the axial direction in a space between the vibration-isolating base (103) and the second fitting (102). A main liquid chamber (107) is formed between the vibration-proof substrate (103) and the partition member (104), and a sub-liquid chamber (107) is formed between the partition member (104) and the first diaphragm (105). 108) is formed. In addition, an equilibrium chamber (109) is formed between the first diaphragm (105) and the second diaphragm (106), and an atmospheric pressure and a negative pressure are provided between the second diaphragm (106) and the second fitting (102). A switching chamber (110) capable of selectively introducing pressure is formed. The partition member (104) is provided with an outer orifice (113) for communicating the main liquid chamber (107) and the sub liquid chamber (108), and an inner orifice (114) diametrically inside the orifice. A coil spring (127) for pressing the first diaphragm (105) against the partition member (104) is disposed in the switching chamber (110) via the second diaphragm (106). A pipe (128) for introducing atmospheric pressure and negative pressure into the switching chamber (110) is provided through the bottom wall of the second fitting (102). When the atmospheric pressure is introduced to (110), the first diaphragm (105) is pressed by the partition member (104) by the coil spring (127), and the liquid between the inner orifice (114) and the sub liquid chamber (108) is discharged. The flow is blocked, and a negative pressure is introduced from the pipe (128) into the switching chamber (110), so that the first diaphragm (105) moves against the urging force of the coil spring (127), whereby the partition member is moved. The inner orifice (114) and the auxiliary liquid chamber (108) communicate with each other. As described above, the vibration isolator can selectively switch between the introduction of the atmospheric pressure and the introduction of the negative pressure into the switching chamber (110), thereby making the inner orifice (114) openable and closable. An orifice corresponding to each vibration can be selectively used.
In this known vibration isolator, a pipe (128) for introducing atmospheric pressure and negative pressure into the switching chamber (110) projects from the bottom surface of the second fitting (102) by welding or the like. It is attached and fixed. When the pipe (128) protrudes in this manner, when the vibration isolator is mounted on a work table or a carrier at a stage before the vibration isolator is mounted on the vehicle, the vibration is prevented by the pipe (128). The pipe (128) may come off because of the weight of the device. This pipe (128) is usually fixed so that it is difficult to come off from the second fixture (102) in consideration of the state after being mounted on the vehicle. 110), it is weak against the load in the pushing direction, and therefore, the problem of detachment of the pipe (128) before mounting on the vehicle is likely to occur.
[Disclosure of the Invention]
The present invention has been made in view of the above, and by selectively switching between the introduction of the atmospheric pressure and the introduction of the negative pressure in the switching chamber, the inner orifice of the inner and outer two orifices can be opened and closed, and shake vibration and In a liquid-filled type vibration damping device that can selectively use orifices corresponding to two vibrations with different frequency ranges, such as idle vibration, to prevent the pipe that introduces atmospheric pressure and negative pressure into the switching chamber from coming off With the goal.
The switchable liquid-filled type vibration damping device of the present invention has a first mounting member and a bottomed cylindrical shape, the bottom wall of which is located at a predetermined axial distance from the first mounting member. A mounting member, a vibration-isolating base made of a rubber elastic body interposed between the first mounting member and the second mounting member, and connecting the two mounting members to each other; A partition member, a first diaphragm and a second diaphragm, which are disposed in series in the axial direction in a space between the first and second liquid chambers formed between the vibration-proof base and the partition member. A second liquid chamber formed between the partition member and the first diaphragm, an outer orifice provided in the partition member for communicating the first liquid chamber and the second liquid chamber, An inner inner orifice and a balance formed between the first and second diaphragms A switching chamber formed between the second diaphragm and a bottom wall of the second mounting member and capable of selectively introducing atmospheric pressure and negative pressure; and a switching chamber for pressing the first diaphragm against a partition member. The first diaphragm is pressed by the partitioning member by the urging means to close the inner orifice, and introduces a negative pressure into the switching chamber by introducing atmospheric pressure into the switching chamber. In this case, the first diaphragm is detached from the partition member against the urging force of the urging means to open the inner orifice. A part of the bottom wall of the tool is depressed toward the switching chamber, and a pipe for introducing atmospheric pressure and negative pressure into the switching chamber is pierced at the top of the depressed part and is accommodated in the depressed part. Outward on the bottom wall around the part In which a plurality of convex portions protruding is provided.
By providing the recessed portion on the bottom wall of the second fixture and housing the introduction pipe inside the recess, it is possible to prevent the pipe from projecting downward from the bottom surface of the second fixture. Therefore, when the vibration isolator is placed on a work table or a carrier before being mounted on the vehicle, the pipe does not support the weight of the vibration isolator, and the pipe can be reliably prevented from coming off.
It is preferable that the introduction pipe is completely accommodated in the depression. However, due to the design of the apparatus, the pipe may be forced to protrude slightly downward from the depression. That is, in order to connect the pipe from the switching valve when mounted on the vehicle, it is necessary to protrude to some extent from the switching chamber to the outside, and the height of the recessed portion depends on the axial dimension of the switching chamber, etc. Be restricted. According to the anti-vibration device of the present invention, even in such a case, the outwardly protruding portion provided around the recessed portion allows the pipe and the mounting surface such as the work table or the carriage to be placed. Interference can be avoided.
In the vibration damping device of the present invention, a press-fit area of the second diaphragm is secured at a peripheral portion of a bottom wall of the second fitting, and the second diaphragm is press-fitted from an upper opening side of the second fitting. It may be fixed in the press-fit area. This eliminates the need to caulk and fix the second diaphragm together with the second fitting.
In the vibration isolator according to the present invention, the urging means is disposed between the bottom wall of the second mounting member and the second diaphragm in the switching chamber, and the first diaphragm is provided via the second diaphragm. To the partition member, the receiving surface of the coil spring is secured on the bottom wall around the recess in the second mounting tool, and the coil spring surrounds the recess. It may be arranged on the receiving surface. As described above, the receiving surface of the coil spring is secured around the recess for accommodating the pipe, and the coil spring is disposed so as to surround the recess, so that the lower end of the coil spring is positioned on the outer periphery of the recess. The displacement of the coil spring on the bottom wall of the second attachment can be prevented.
In the vibration damping device of the present invention, a stopper rubber portion is provided on the second diaphragm, and a contact surface of the stopper rubber portion is secured on a bottom wall around the recessed portion of the second mounting fixture. Is also good. Thus, it is possible to limit unnecessary displacement of the second diaphragm downward below when the negative pressure is introduced into the switching chamber.
In this case, the convex portion can be provided on a bottom wall portion corresponding to a contact surface of the stopper rubber portion. Since the contact surface with the stopper rubber portion does not need to be secured over the entire circumferential direction, a convex portion can be provided in this portion without impairing the performance.
In the vibration damping device of the present invention, the depression is provided at the center of the bottom wall of the second mounting tool, and the receiving surface of the coil spring is secured therearound. A contact surface of the stopper rubber portion may be secured between the press-fitting region of the second diaphragm and the second diaphragm.
[Best mode for carrying out the invention]
Next, a switching type liquid filled type vibration damping device according to an embodiment of the present invention will be described with reference to the drawings.
The switchable liquid-filled type vibration damping device has a first mounting member (1) and a bottomed cylindrical shape, the bottom of which is located at a predetermined distance in the axial direction from the first mounting member (1). (2) a thick vibration isolator made of a rubber elastic body, which is interposed between the first fitting (1) and the second fitting (2) to connect the two fittings to each other; And a base (3).
The first mounting member (1) has a substantially frame shape formed of a rigid material such as a metal material, and has a mounting bolt (1a) protruding from a central portion thereof. The first mounting member (1) is mounted mainly on the power unit such as an automobile engine, that is, on the vibrating body side by the mounting bolts (1a).
The second fixture (2) is also formed of a rigid material such as a metal material. In the case of this embodiment, the second fitting (2) includes a cylindrical metal fitting (21) whose upper part is vulcanized and bonded to the vibration-proof base (3), a bottom wall (22) and a cylindrical side wall (23). And a flange-shaped upper end (23a) of a side wall (23) of the lid (24) is caulked and fixed to a lower end (21a) of the tubular metal (21). I have. The second attachment (2) is attached mainly to the vehicle body by a bracket (not shown) attached to the outer periphery of the cylindrical fitting (21) and / or the lid fitting (24). A stopper fitting (30) is attached to the outer periphery of the upper part of the cylindrical fitting (24) so as to accommodate the vibration-proof base (3).
As shown in the drawing, the vibration-isolating substrate (3) has a substantially umbrella shape, and is joined by vulcanization bonding means in a state where the first fitting (1) is embedded in the upper part. A cylindrical fitting (21) of a second fixture (2) is vulcanized and bonded to the outer periphery of the lower portion of the vibration-proof base (3).
In the space between the anti-vibration base (3) and the bottom wall (22) of the second fixture (2), the partition member (4) and the rubber film are arranged in order from the side of the anti-vibration base (3). A first diaphragm (5) and a second diaphragm (6) are arranged in series in the axial direction. Further, a space between the vibration-proof base (3) and the partition member (4) is formed as a main liquid chamber (7) in which a liquid is sealed, and a space between the partition member (4) and the first diaphragm (5) is an orifice described later. And a sub-liquid chamber (8) communicating with the main liquid chamber (7).
Further, a space between the first diaphragm (5) and the second diaphragm (6) is opened to the atmosphere through a ventilation hole (23b) provided in a side wall (23) of a lid (24) of the second mounting member (2). (9). In addition, a space between the second diaphragm (6) and the bottom wall (22) of the cover fitting (24) covering the lower surface of the second diaphragm (6) is a switching chamber (10) capable of selectively introducing atmospheric pressure and negative pressure. The switching chamber (10) is switched between an atmospheric pressure introducing state and a negative pressure introducing state by an external switching valve (not shown) through a pipe (11) to be described later, so as to change its volume. Further, the equilibrium chamber (9) has a function of reducing the pressure difference between the sub liquid chamber (8) and the switching chamber (10), which can contribute to the durability of the diaphragms (5) and (6), The control can be performed by introducing a small negative pressure into the switching chamber (10). Note that the equilibrium chamber (9) may be a sealed chamber.
The partition member (4) includes a first member (41) which is a molded body made of a metal such as aluminum, a synthetic resin, or another rigid material, and a metal member disposed on a lower surface of the first member (41). It is composed of two members (42). The first member (41) has a circumferentially extending groove for forming an outer orifice (12) along its outer circumference, and a circumferential direction for forming an inner orifice (13) on the lower surface side inside the first member (41). Having a groove extending therethrough. The first member (41) is provided together with the second member (42) on the inner periphery of the lower opening side of the cylindrical metal fitting (21) of the second mounting member (2). It is fitted airtight through a part (3a), whereby the groove on the outer periphery constitutes a passage as an outer orifice (12). The inside groove is configured to form a passage as the inside orifice (13) by the second member (42) closing the lower surface of the first member (41). The outlet (13a) of the inner orifice (13) to the side of the sub liquid chamber (8) is formed by opening the center of the partition member (4) downward.
In addition, the outer orifice (12) is formed to have a longer flow path length than the inner orifice (13), or by setting the cross-sectional area of the flow path to be smaller, so that the lower orifice (12) has a lower cross-sectional area. The vibration damping effect is effectively exerted in the shake vibration frequency range), and the inner orifice (13) can effectively exert the vibration damping effect in the high frequency range (idle vibration frequency range). It has been done.
The first diaphragm (5) has an annular collar (51) vulcanized and bonded to the outer periphery thereof, and the collar (51) is composed of the above-described tubular fitting (21) and lid fitting (24). The caulking fixing portion is caulked and fixed integrally with the periphery of the second member (42) of the partition member (4). At the center of the first diaphragm (5), a valve body (52) that can close the outlet (13a) of the inner orifice (13) coaxially with the outlet (13a) is integrally formed. The valve body (52) has a slightly thicker flat rubber surface (53) which comes into contact with the lower surface of the periphery of the inner orifice (13) in the partition member (4), and has a central portion of the flat rubber surface (53). And has a protrusion (54) for preventing lateral displacement fitted into the inner orifice (13), and the valve body (52) is in a state where the protrusion (54) is fitted into the outlet (13a). ) Can be moved up and down to open and close the inner orifice (13).
The second diaphragm (6) is connected to the annular rubber portion (61) slightly thicker than the rubber film of the first diaphragm (5) and the inner peripheral edge of the rubber portion (61), and is connected to the valve body (52). A pressing auxiliary member (62) having a substantially cap-shaped cross section for pressing the flat rubber surface (53) from the equilibrium chamber (9) side to the partition member (4), and via the pressing auxiliary member (62); The valve body (52) is provided to move up and down. The second diaphragm (6) has a cylindrical ring-shaped fitting (63) vulcanized and bonded to an outer peripheral portion thereof, and the outer peripheral portion has a side wall (24) of a lid fitting (24) of the second fitting (2). 23) is press-fitted and fixed to the lower end portion so as to maintain an airtight state. Note that the diameter of the lower side of the side wall (23) of the lid fitting (24) is slightly smaller than that of the upper side through the step portion (23c), and the second diaphragm (6) is provided on the lower side of the small diameter. Is press-fitted. Further, the second diaphragm (6) has a pressing auxiliary member so that the projecting portion (54) of the valve body (52) does not come off from the inside of the inner orifice (14) when negative pressure is introduced into the switching chamber (10). A stopper rubber portion (65) for restricting the lowering of (62) is provided by rubber integral with the rubber portion (61).
In the switching chamber (10), urging means for pressing the valve body (52) of the first diaphragm (5) against the partition member (4) via the pressing auxiliary member (62) of the second diaphragm (6). The coil spring (14) is disposed. The coil spring (14) is provided between the step (64) of the pressing auxiliary member (62) and the bottom wall (22) side of the lid (24).
A pipe (11) for introducing atmospheric pressure and negative pressure into the switching chamber (10) penetrates through the bottom wall (22) of the lid fitting (24) of the second fitting (2). As shown in FIGS. 1 and 3, the bottom wall (22) is provided with its central portion depressed upward, that is, toward the switching chamber (10). That is, the central portion of the bottom wall (22) is formed into a substantially truncated conical shape by drawing so as to protrude toward the inside of the switching chamber (10). The pipe (11) is fixedly mounted on the horizontal pipe mounting surface (25a) at the top of the depression (25) by resistance welding. The pipe (11) is housed in a space inside the depression (25) such that its lower end does not protrude downward from the bottom surface of the lid (24).
On the bottom wall (22) of the cover fitting (24), an annular portion for receiving the lower end of the coil spring (14) disposed in the switching chamber (10) is provided on the outer periphery of the base end of the depression (25). The spring receiving surface (26) is secured. The coil spring (14) is disposed on the spring receiving surface (26) so as to surround the depression (25), and is positioned on the outer periphery of the depression (25).
The bottom wall (22) of the cover fitting (24) is also provided with a press-fit area (27) for the second diaphragm (6) at the periphery thereof. The second diaphragm (6) is press-fitted from the upper opening side of the lid (24), and in the press-fitting region, the outer peripheral portion is fitted and fixed to the inner peripheral surface of the side wall (23).
The bottom wall (22) of the lid fitting (24) is further provided with a contact surface of the stopper rubber portion (65) between the spring receiving surface (26) and the press-fit region (27). (28) is secured. When a negative pressure is introduced into the switching chamber (10), the stopper rubber portion (65) comes into contact with the contact surface (28), so that the pressing auxiliary member (62) of the second diaphragm (6) is lowered by a predetermined amount or more. Be regulated.
As shown in FIGS. 1 and 4, the bottom wall (22) of the lid (24) is provided with a plurality of circular projections (29) slightly projecting downward, that is, outwardly. I have. Even when the lower end of the pipe (11) projects slightly from the bottom surface of the lid (24), the convex portion (29) can make contact with the pipe (11) and a mounting surface such as a work table or a carrier. This is for avoiding interference. That is, the lower end of the pipe (11) terminates in the depression (25) or above the lower surface of the projection (29), if any, protruding from the depression (25). Interference with the mounting surface is avoided. It is preferable that three or more protrusions (29) are provided in the circumferential direction, and in this embodiment, four protrusions (29) are provided at equal intervals in the circumferential direction. The protrusion (29) is provided at a position corresponding to the contact surface (28) with the stopper rubber portion (65). Since the contact surface (28) with the stopper rubber portion (65) does not need to be secured over the entire circumferential direction, if this portion is used, the protrusion (29) for avoiding interference can be provided without impairing the performance. Can be provided.
In the switchable liquid-filled type vibration damping device configured as described above, the vibration damping base (3) is deformed by the vibration applied from the vibrating body side such as the power unit, and the liquid in the main liquid chamber (7) is deformed by the deformation. The liquid flows into and out of the auxiliary liquid chamber (8) through the outer orifice (12) or the inner orifice (13) of the partition member (4), and at this time, the outer orifice (12) and the inner orifice (13) respectively. The vibration characteristics are greatly attenuated by the resonance characteristics of
FIG. 1 shows a state in which the switching chamber (10) is supplied with the atmospheric pressure through a pipe (11), and a valve element (52) provided at the center of the first diaphragm (5) has a biasing force of a coil spring (14). Is pressed toward the partition member (4) via the pressing auxiliary member (62), so that the flat rubber surface (53) of the valve body (52) comes into contact with the lower surface of the partition member (4) and the inner orifice (13). ) Is blocked. Therefore, the liquid flows between the main liquid chamber (7) and the sub liquid chamber (8) through the outer orifice (12). Therefore, vibration in a frequency range in which the damping action can be effectively performed by the outer orifice (12), for example, shake vibration, can be effectively damped.
On the other hand, FIG. 2 shows a state in which a negative pressure is introduced into the switching chamber (10). In this case, when the switching chamber (10) becomes negative pressure, the second diaphragm (6) is sucked together with the pressing auxiliary member (62) toward the bottom wall (22) of the second fitting (2), and Along with this, it moves downward together with the valve element (52) against the urging force of the coil spring (14), the flat rubber surface (53) separates from the lower surface of the partition member (4), and the inner orifice (13) Is opened to the sub liquid chamber (8), and the main liquid chamber (7) and the sub liquid chamber (8) are in communication. At this time, since the inner orifice (13) has a larger sectional area and a shorter liquid flow distance than the outer orifice (12), the liquid does not flow through the outer orifice (12) without flowing through the inner orifice (13). , And the vibration in the frequency range in which the damping action can be effectively performed by the inner orifice (13), that is, the idle vibration can be effectively attenuated.
According to the liquid filling type vibration damping device of the present embodiment described above, a depression (25) is provided in the bottom wall (22) of the second mounting tool (2), and the introduction pipe (11) is provided inside the depression (25). And the pipe (11) does not protrude downward from the bottom surface of the second fitting (2) by providing a projection (29) for avoiding interference around the depression (25). Therefore, when the anti-vibration device is mounted on a work table or a transport platform before the vehicle is mounted, the weight of the anti-vibration device is not supported by the pipe (11), and the pipe (11) can be securely removed. Can be prevented.
The bottom wall (22) has a receiving surface (26) for the coil spring (14), a press-fit area (27) for the second diaphragm (6), and a contact surface (28) for the stopper rubber portion (65). By providing the above-described depression (25) for accommodating the pipe, the problem of the pipe detachment can be solved without impairing the performance of the switchable liquid-filled type vibration damping device.
[Industrial applicability]
As described above, according to the present invention, a pipe for introducing atmospheric pressure and negative pressure into the switching chamber can be reliably prevented from coming off, and a switching type liquid filled type vibration damping apparatus having a low defect rate and excellent productivity. Can be provided.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing a state in which atmospheric pressure is introduced into a switching chamber of a switchable liquid filled type vibration damping device according to one embodiment of the present invention,
FIG. 2 is a vertical cross-sectional view of a state where a negative pressure is introduced into the switching chamber of the device,
FIG. 3 is a partially cutaway perspective view of a lid fitting that constitutes a second fitting of the apparatus.
FIG. 4 is a plan view of the lid fitting,
FIG. 5 is a longitudinal sectional view of a conventional switchable liquid-filled type vibration damping device.

Claims (6)

A first fixture;
A second fixture having a bottomed cylindrical shape and a bottom wall of which is located at a predetermined distance in the axial direction from the first fixture;
An anti-vibration base made of a rubber elastic body interposed between the first fixture and the second fixture and connecting the two fixtures to each other;
A partition member, a first diaphragm and a second diaphragm, which are arranged in series in the axial direction in a space between the vibration-isolating base and the second mounting member;
A first liquid chamber formed between the vibration isolation base and the partition member;
A second liquid chamber formed between the partition member and the first diaphragm;
An outer orifice and an inner orifice located diametrically inwardly of the outer orifice provided in the partition member for communicating the first and second liquid chambers;
An equilibrium chamber formed between the first and second diaphragms,
A switching chamber formed between the second diaphragm and the bottom wall of the second fitting, and capable of selectively introducing atmospheric pressure and negative pressure;
Urging means for pressing the first diaphragm against the partition member,
By introducing atmospheric pressure into the switching chamber, the first diaphragm is pressed against the partition member by the urging means to close the inner orifice,
By introducing a negative pressure into the switching chamber, the first diaphragm is separated from the partition member against the urging force of the urging means and the inner orifice is opened, so that a liquid-filled type barrier is provided. In the vibration device,
A part of the bottom wall of the second fitting is depressed toward the switching chamber, and a pipe for introducing atmospheric pressure and negative pressure into the switching chamber is penetrated at the top of the depressed part and accommodated in the depressed part. And
A switchable liquid-filled type vibration damping device, wherein a plurality of projections projecting outward are provided on a bottom wall around the depression. A press-fit region of the second diaphragm is secured at a peripheral portion of a bottom wall of the second fixture, and the second diaphragm is press-fitted from an upper opening side of the second fixture and fixed in the press-fit region. 2. The switchable liquid-filled vibration damping device according to claim 1, wherein: The urging means is disposed between the bottom wall of the second fixture and the second diaphragm in the switching chamber, and presses the first diaphragm against the partition member via the second diaphragm. A coil spring,
The receiving surface of the coil spring is secured on a bottom wall around the depression in the second fixture, and the coil spring is disposed on the reception surface so as to surround the depression. Item 3. A switchable liquid-filled type vibration damping device according to Item 1 or 2. 4. The stopper according to claim 1, wherein a stopper rubber portion is provided on the second diaphragm, and a contact surface of the stopper rubber portion is secured on a bottom wall around the depression in the second attachment. The switchable liquid-filled type vibration damping device according to any one of the above. The switchable liquid-filled type vibration damping device according to claim 4, wherein the convex portion is provided on a bottom wall portion corresponding to a contact surface of the stopper rubber portion. A stopper rubber portion is provided on the second diaphragm,
The urging means is disposed between the bottom wall of the second fixture and the second diaphragm in the switching chamber, and presses the first diaphragm against the partition member via the second diaphragm. A coil spring,
The depressed portion is provided at the center of the bottom wall of the second mounting tool, around which the receiving surface of the coil spring is secured, and the second diaphragm is provided at the peripheral edge of the bottom wall of the second mounting tool. A press contact area of the stopper rubber portion is secured between the receiving surface and the press fit area of the second diaphragm,
The said coil spring was arrange | positioned on the said receiving surface so as to surround the said recessed part, The said 2nd diaphragm was press-fitted from the upper opening side of the said 2nd mounting fixture, and was fixed in the said press-fit area. Item 2. A switchable liquid-filled type vibration damping device according to Item 1.

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